Mechanolysis of Glucose-Based Polysaccharides As Studied by Electron Spin Resonance

Kuzuya, Masayuki; Yamauchi, Yukiko; Kondo, Shinichi

doi:10.1021/jp984278d

Cited by 89 publications

(69 citation statements)

References 45 publications

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“…3A that the radical concentration more readily decreased after reaching the maximum value in each polysaccharide, although cellulose required much longer vibratory milling (120 min) to exhibit the maximum value in the mechanoradical concentrations. 23) In the case of plasmolysis, however, the radical concentrations tended to level off in all plasma-irradiated polysaccharides (Fig. 3B).…”

Section: Results and Discussion Observed Esr Spectra Of Substituted Pmentioning

confidence: 85%

“…23) Consequently, the timecourse changes in mechanoradical concentration shown in Fig. 3A indicate that the ensuing reactions of the mechanoradical formed exceed the radical generation, as the molecular weights of polysaccharides come close to the limiting value, and that substituted celluloses are more prone than cellulose to undergo the ensuing radical reactions such as a recombination reaction due to mechanical force.…”

Section: Results and Discussion Observed Esr Spectra Of Substituted Pmentioning

confidence: 95%

“…5 that the ratio of change in each spectral intensity does not vary much with component spectra, accounting for rather small spectral changes in pattern in the course of mechanolysis and plasmolysis in each case. Although the broad singleline spectrum was the major spectral component in the mechanolysis of both cellulose and amylose, 23) this was not the case for substituted celluloses.…”

Section: Results and Discussion Observed Esr Spectra Of Substituted Pmentioning

confidence: 99%

“…We reported detailed analyses of room-temperature ESR spectra of the mechanoradicals formed in synthetic polymers 21,22) and polysaccharides such as cellulose and amylose 23) under strictly anaerobic conditions, and discussed the novel and significant features of mechanoradical formation and changes in physicochemical properties caused by the mechanolysis.…”

Section: Monosaccharides (A-and B-glucose)mentioning

confidence: 99%

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Nature of Mechanoradical Formation of Substituted Celluloses as Studied by Electron Spin Resonance

Sasai

Yamauchi

Kondo

et al. 2004

CHEMICAL & PHARMACEUTICAL BULLETIN

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Over the years, we have reported on the electron-spin resonance (ESR) elucidation of the plasma-induced radicals of a variety of glucose-based saccharides, such as myo-inositol, 1) monosaccharides (a-and b-glucose),2) disaccharides (maltose and cellobiose), 3) and polysaccharides (cellulose and amylose), 4) ethyl-and hydroxyethylcellulose (EC and HEC), 5) and low-and high-substituted hydroxypropylcellulose (L-HPC and H-HPC). 6) We have further undertaken the characterization of the plasma-induced radicals of several other substituted celluloses such as carboxylmethylcellulose (CMC), 2-acetamido-2-deoxycellulose (chitin), and 2-amino-2-deoxycellulose (chitosan) 7) in response to the need for experimental design in a series of studies on novel plasma-assisted drug-delivery system (DDS) preparations. [8][9][10][11][12][13][14][15][16][17][18][19] The substituted celluloses thus far studied are all pharmaceutically important polymers used as pharmaceutical aids and food additives. The study of mechanolysis is of fundamental significance in connection with the manufacture of a wide variety of solid materials in industry. Polymers including polysaccharides in powdered form are also often used in a variety of industrial fields. It has been known that mechanolysis of polymers, synthetic and natural, results in mechanically induced radicals, so-called mechanoradicals, due to the polymer main-chain scission when the glass transition temperature (T g ) of the polymers exceeds the temperature at which the mechanolysis is conducted. Little attention has been paid, however, to the formation of mechanoradicals in many fields of industry including pharmaceutical engineering, although mechanoradical formation results in more or less the same changes in physicochemical properties resulting from the decrease in molecular weight due to main-chain scission and its ensuing processes such as the reaction of recombination and disproportionation.ESR studies of mechanoradical formation reported previously dealt with polymers ground at low temperature (77 K), 20) and no such study at room temperature has been carried out, although in practice most operations of grinding and/or ball milling are conducted at room temperature.We reported detailed analyses of room-temperature ESR spectra of the mechanoradicals formed in synthetic polymers 21,22) and polysaccharides such as cellulose and amylose 23) under strictly anaerobic conditions, and discussed the novel and significant features of mechanoradical formation and changes in physicochemical properties caused by the mechanolysis.In this paper, we report on mechanoradical formation and the reactivities of several pharmaceutically important substituted celluloses such as CMC, chitin, and chitosan ( Fig. 1), in comparison with those of plasma-irradiated samples, as studied by ESR coupled with systematic computer simulations. Among various substituted celluloses, we selected in the present study three derivatives with substituents capable of intense intermolecular interactions. ExperimentalMateria...

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Section: Results and Discussion Observed Esr Spectra Of Substituted Pmentioning

confidence: 85%

Section: Results and Discussion Observed Esr Spectra Of Substituted Pmentioning

confidence: 95%

Section: Results and Discussion Observed Esr Spectra Of Substituted Pmentioning

confidence: 99%

Section: Monosaccharides (A-and B-glucose)mentioning

confidence: 99%

See 2 more Smart Citations

Nature of Mechanoradical Formation of Substituted Celluloses as Studied by Electron Spin Resonance

Sasai

Yamauchi

Kondo

et al. 2004

CHEMICAL & PHARMACEUTICAL BULLETIN

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“…The values of its HFS splitting were significantly higher than those observed for signals of semiquinone radicals [26]; hence, we ascribed tentatively signal III to carbohydrate radical. The formation of such centre could occur under the influence of solar, mechanical, irradiation or thermal energy and was observed in living plants, as well as in other biological materials subjected to c-irradiation, heating or grinding [27][28][29][30][31] Fig. 1 The experimental (exp) and simulated (sim) EPR spectra of different kinds of teas, registered at 293 K, at 3 mW, in the range 5 mT and their particular signal components (I, II, III, IV) used to simulation of the spectra: a Teekane black, b Lipton black, c Lipton green, d Bio-Active green, e Yunnan white I, II-signals of semiquinone radicals, III-carbohydrate radical localised at C(1) atom of glucose, IV-carbohydrate radical localised at C(1) atom of glucose unit in oligosaccharide structure created after dehydration b probably mono or disaccharides [31][32][33].…”

Section: Commercial Name (?)-C (-)-Ec (-)-Egcg (-)-Ecg (-)-Egc Totalmentioning

confidence: 99%

Determination of free radicals and flavan-3-ols content in fermented and unfermented teas and properties of their infusions

Socha

Bączkowicz

Fortuna

et al. 2013

Eur Food Res Technol

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The objective of this study was to analyse selected brands of fermented (red and black) and unfermented (white and green) teas for free radical content with the use of electron paramagnetic resonance (EPR) spectroscopy and for contents of flavan-3-ols by means of highperformance liquid chromatography. Analyses were also conducted for the polyphenolic profile of infusions of the analysed teas (with the Folin-Ciocalteu's method) and their antioxidant activity (in reaction with a DPPH radical) at three brewing times (5, 10 and 15 min). The obtained results showed the possibility of using rapid spectroscopic method EPR to evaluate the oxidative changes in tea leaves caused by enzymatic fermentation. The number of free radicals in teas was negatively correlated with contents of flavan-3-ols, (-)-EGCG in particular. The main signals observed in EPR spectra of teas were attributed to semiquinone radicals; however, also signals attributed to carbohydrate radicals were detected. Regarding unfermented teas, it was ascertained that teas with the highest content of flavan-3-ols, (-)-EGCG in particular, were characterised by the lowest content of semiquinone radicals and a high content of carbohydrate radicals. The group of fermented teas demonstrated to contain mainly semiquinone radicals. The total phenolic content and antioxidant activity of the tea infusions were strongly diversified depending on the kind and brand of tea as well as on the extraction time. The predominating flavan-3-ol in the analysed teas was epigallocatechin gallate (-)-EGCG, the content of which was additionally highly correlated with the antioxidant activity of the tea infusions.

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Mechanochemical Reactions of Polymers

Beyer

2014

Encyclopedia of Polymer Science and Technology

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An external mechanical force is able to activate covalent bonds. Grinding, milling, or extrusion of polymers and polymeric materials leads to polymer degradation, because covalent bonds are broken. Mechanoradicals are generated by homolytic rupture of covalent bonds, but bond hydrolysis or other bimolecular reactions may as well be mechanically activated. Rubber mastication, thermomechanical treatment of food polymers, and recycling of postconsumer plastic waste are technological applications of mechanochemical reactions of polymers. The design of mechanophores opens new possibilities for mechanoresponsive materials. Weak linkages introduce defined rupture points in polymers. Mechanochromic mechanophores lead to color change of polymer solids when exposed to excessive mechanical stress, even before macroscopic damage becomes visible. Further examples are chemiluminescent mechanophores, cross‐linking mechanophores, or mechanophores acting as mechanocatalysts. A quantitative understanding of mechanochemical reactions is reached with a wide variety of experimental and theoretical methods. Defined force can be applied to the bulk material, as well as to individual molecules embedded in macrocycles, or single polymer chains manipulated with an atomic force microscope. The latter method forms the basis for single molecule force spectroscopy, which is performed either in the force‐ramp or force‐clamp mode. The theoretical framework ranges from one‐dimensional description of covalent bonds with a Morse potential via the constrained geometries simulate external force method to full‐dimensional quantum chemical methods like external force explicitly included or the force‐modified potential energy surface. Ab initio molecular dynamics simulations, transition state optimizations, or intrinsic reaction paths following are routinely performed on molecules exposed to a defined mechanical force.

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Mechanolysis of Glucose-Based Polysaccharides As Studied by Electron Spin Resonance

Cited by 89 publications

References 45 publications

Nature of Mechanoradical Formation of Substituted Celluloses as Studied by Electron Spin Resonance

Nature of Mechanoradical Formation of Substituted Celluloses as Studied by Electron Spin Resonance

Determination of free radicals and flavan-3-ols content in fermented and unfermented teas and properties of their infusions

Mechanochemical Reactions of Polymers

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